KR102245281B1 - Error Intensive Monitoring and Controllable Emergency Control System for Power Management System and Battery Management System - Google Patents

Abstract

The present invention relates to an emergency control system capable of intensively monitoring and controlling abnormalities in a power conversion system and a battery management system, which performs independent monitoring and control of data of the power conversion system and the battery management system of each facility constituting an energy storage device through communication to determine whether there is an abnormality and to control the corresponding facility in an emergency through rapid response, and thus it is possible to prevent the occurrence of a fire in the energy storage device. The present invention greatly shortens a communication cycle, so that a quick response is possible in case of the abnormality.

Description

[Error Intensive Monitoring and Controllable Emergency Control System for Power Management System and Battery Management System]

The present invention relates to an emergency control system capable of intensive monitoring and control of abnormalities in a power conversion system and a battery management system, and more particularly, to communicate data of a power conversion system and a battery management system among facilities constituting an energy storage device. The power conversion system and battery management system are intensively monitored and controlled for abnormalities through independent monitoring and control to determine whether there is an abnormality, and to prevent fires in the energy storage device through rapid response by controlling the facility in an emergency situation. It relates to a possible emergency control system.

The Energy Storage System (ESS) receives the power produced by the power plant during the low-cost light load period, charges it in a large-capacity power storage battery, and discharges it at the time when power is needed or during the heavy load period. Refers to the supported system.

As shown in FIG. 4, the energy storage device includes a power management system 110 (PMS; Power Management System) that stores power from the grid power grid connected to the power plant in a battery or controls the power of the battery to be supplied to the grid power grid, A battery management system (120, BMS; Battery Management System) that manages a battery that stores power supplied from the grid and performs data communication with the power management system 110, and converts the power stored in the battery to AC/DC. A power conversion system (40, PCS; Power Conditioning System) for performing data communication with the power management system 110 by DC/AC conversion of the power charged or stored in the battery and supplying it to the grid power grid or load, and the power management system 110 ), including an energy management system 140 (EMS; Energy Management System) that manages energy by controlling each system through data communication, and a watt hour meter 150 that displays the amount of power input and output from the grid power grid, and the power is converted to AC. It includes a converter (170, DC) and other equipment 160 for converting /DC or DC/AC conversion.

At this time, the battery is configured by electrically connecting a certain number of lithium-ion batteries to a multi-stage rack in a modular structure, and is usually installed in a battery storage located inside a container called a housing, and the power conversion device 130 and energy It is organically coupled to the management system 140 and the like. However, since the battery of the energy storage device stores energy at a high density, an accident may occur due to overheating or being easily exposed to fire and explosion risks depending on internal and external environments.

Accordingly, the energy storage device is equipped with a safety system that can prevent fire and extinguish a fire quickly.This safety system has a structure that cuts off power and extinguishes fire when the temperature of the battery storage rises or a fire occurs. have.

However, the safety system of the conventional energy storage device described above has a problem that it cannot fundamentally block the occurrence of a fire, and the power management system that receives and controls the data of the energy storage device is a power conversion system and a battery management system. Of course, communication with many devices constituting the energy storage device is performed and stored in the database, so it is difficult to respond immediately in an emergency situation as the communication cycle is prolonged. There are many problems that are difficult to proceed in.

In addition, as the power management system communicates with many devices constituting the energy storage device, there is another problem in that a gap between the data at the time of occurrence of an anomaly occurs as data exchanged at a relatively long period is stored in the database.

Meanwhile, as a result of researching the prior art related to the present invention, a number of patent documents have been searched, and some of them are as follows.

Patent Document 1, N battery groups including a plurality of battery racks (Battery Rack); N power conversion modules connected 1:1 with the N battery groups to charge and discharge the battery groups; A first controller that generates a power command value for each power conversion module and controls the power conversion module so that the power conversion module charges and discharges the battery group according to the power command value; And if there is a target battery rack that is a battery rack in which an abnormality has occurred, it is determined whether the target battery rack can be detached according to the current charge/discharge power amount of the battery energy storage system, and if the target battery rack is detachable, the power conversion module And a BESS controller that generates a first control command for changing a power command value of and transmits the first control command to the first controller, wherein the first controller, when the first control command is received from the BESS controller, the target battery rack It is configured to change the power command value of the target power conversion module connected to the target battery group so that no current flows through the included target battery group, so that emergency operation in the event of an error in the battery rack, which enables continuous operation without deteriorating the efficiency of the battery energy storage system. A battery energy storage system capable of this is disclosed.

Patent Document 2, a plurality of lithium battery modules loaded in a plurality of lithium battery racks, an EOG sensor module for sensing electrolyte discharge gas generated from a lithium battery cell constituting the plurality of lithium battery modules, and the plurality of lithium Lithium battery system consisting of a lithium battery management system for controlling the management, charging and discharging operation of the battery module; A power conversion system that controls the lithium battery management system and provides data and information to a remote monitoring system; And a remote monitoring system for receiving, storing and managing data from the EOG sensor module; including, and preventing a fire through detection of an adaptive lithium battery electrolyte exhaust gas in the surrounding environment, and a fire in the electric energy storage system and the electric energy storage system. Disclosing preventive measures.

Patent Document 3, in the emergency cut-off circuit connected to the wiring located between the power system and the energy storage system, the emergency cut-off switch located on the first branch line branched from the wiring, which can be opened by an operator; A first relay coil connected in series with the emergency shut-off switch; A second relay coil connected in parallel to the emergency shut-off switch and the first relay coil; A first contact located on a second branch line branched from the wiring and interlocked with the first relay coil; A second contact interlocked with the second relay coil and connected in series with the first contact; And a circuit breaker that is electrically connected to the second branch line and operates when no current flows through the second branch line, and an emergency cut-off circuit for an energy storage system capable of smoothly operating respectively for power failure and recovery situations. Is initiating.

Patent Literature 4 discloses that a part of the power supplied from the wind generator is always charged to the battery, or the power stored in the battery is discharged to the power system, and when an abnormality is detected in the power system, the power stored in the battery is discharged. A battery energy storage device supplying emergency power to a wind power generation control device that controls the wind power generator; And a backflow prevention unit for preventing reverse flow of power discharged from the battery to the power system by blocking the connection with the power system when an abnormality in the power system is detected, and power can be supplied to the wind power generation control device in an emergency Disclosed is a battery energy storage system.

KR 10-2015-0087958 A KR 10-2116720 B1 KR 10-2019-0084599 A KR 10-2014-0087932 A

The present invention was conceived to solve the problems of the prior art described above, and determines whether each facility constituting the energy storage device has a failure, and controls each facility so that a fire does not occur. Provides an emergency control system that enables intensive monitoring and control of abnormalities in the power conversion system and battery management system to prevent fires in energy storage devices through rapid response in emergency situations by performing independent monitoring and control through data communication. It has its purpose.

The present invention for achieving the above object is a power management system for storing the power of the grid power grid in a battery or controlling the power of the battery to be supplied to the grid power grid; A battery management system that manages a battery that stores power supplied from the grid power grid and performs data communication with the power management system; A power conversion system that converts and charges the power stored in the battery to AC/DC or converts the power stored in the battery to DC/AC and supplies it to the grid or load, and performs data communication with the power management system; An energy management system that manages energy by controlling each system through data communication with the power management system; As an emergency control system provided in an energy storage device including a watt hour meter and other equipment; abnormalities in the battery management system and the power conversion system using a port other than the communication port of the existing power management system, battery management system, and power conversion system. It consists of a failure monitoring interface that receives only data and controls each facility to determine whether each facility is malfunctioning and to prevent fire, and performs independent monitoring and control through data communication with the battery management system and power conversion system. It is characterized by that.

In addition, according to the emergency control system capable of monitoring and controlling abnormalities in the power conversion system and the battery management system of the present invention, the failure monitoring and control interface includes a data receiving unit for receiving failure data of the battery management system and the power conversion system, and receiving Data recording unit in which fault data is recorded, equipment control unit that controls battery management system or power conversion system based on received fault data, and data that transmits a control signal to equipment control unit by determining whether there is an abnormality according to received fault data It characterized in that it includes a determination unit.

In addition, according to the emergency control system capable of monitoring and controlling abnormalities in the power conversion system and the battery management system of the present invention, the data determination unit determines whether there is an abnormality according to failure data from the battery management system and the power conversion system. Alternatively, it is characterized in that the control information is transmitted to the energy management system to enable secondary supplementation in the power management system or energy management system.

In addition, according to the emergency control system capable of centrally monitoring and controlling abnormalities in the power conversion system and the battery management system of the present invention, the battery management system collects current read data, fault data, protection data, and alarm data. In addition to recording the fault data, the fault data is transmitted to the fault monitoring and control interface through the data transmission unit, and the power conversion system collects the current read data, fault data, and warning data, and records fault data among these data. It is characterized in that the fault data is transmitted to the fault monitoring and control interface through the transmission unit.

In addition, according to the emergency control system capable of intensive monitoring and control of abnormalities in the power conversion system and the battery management system of the present invention, the communication period between the fault monitoring interface and the battery management system or the power conversion system is 0.5 to 1.0 seconds. It is done.

The emergency control system capable of intensive monitoring and control of abnormalities in the power conversion system and battery management system of the present invention greatly shortens the communication cycle as the failure monitoring and control interface is directly connected to the battery management system and the power conversion system to transmit and receive data. In the event of an abnormality, a quick response is possible, thereby preventing an accident such as a fire in the energy storage device.

In addition, according to the emergency control system capable of centrally monitoring and controlling abnormalities in the power conversion system and the battery management system of the present invention, the failure monitoring and control interface receives only critical failure data from the battery management system and the power conversion system. Since only the log is entered through the data recorder without recording in the database, communication of 0.5 to 1 second cycle is possible, and by performing data communication using a port different from the power management system, quick response control is possible. have.

In addition, according to the emergency control system capable of intensive monitoring and control of abnormalities in the power conversion system and the battery management system of the present invention, the data determination unit of the fault monitoring and control interface is a power management system or an energy management system. Since failure data and control results are transmitted, it is possible to supplement the power management system or energy management system for devices that are not normally stopped even through the equipment control unit of the failure monitoring and control interface.

In addition, according to the emergency control system capable of monitoring and controlling abnormalities in the power conversion system and the battery management system of the present invention, failure data of the battery management system and the power conversion system are transmitted every 0.5 to 1 second, By recording the log in the data recording unit, there is an effect of reducing the gap difference in data compared to the conventional method.

1 is a block diagram schematically showing a control flow of an emergency control system capable of monitoring and controlling abnormalities in a power conversion system and a battery management system according to the present invention.
Figure 2 is a block diagram showing the control flow of the fault monitoring and control interface constituting the emergency control system according to the present invention.
Figure 3 is a control flow chart of the emergency control system of the energy storage device according to the present invention.
4 is a block diagram schematically showing the configuration of a general energy storage device.

Hereinafter, an emergency control system capable of intensively monitoring and controlling abnormalities of the power conversion system and the battery management system of the present invention will be described with reference to the accompanying drawings.

The terms used in the present invention are terms defined in consideration of functions in the present invention, and since these may vary according to the intention or custom of users or operators, the definitions of these terms correspond to the technical matters of the present invention. And should be interpreted as a concept.

In addition, the embodiments of the present invention do not limit the scope of the present invention, but are merely exemplary matters of the elements presented in the claims of the present invention, and are included in the technical idea throughout the specification of the present invention. This is an embodiment including a component that can be substituted as an equivalent in the component.

In addition, optional terms in the following embodiments are used to distinguish one component from other components, and the component is not limited by the terms.

Accordingly, in describing the present invention, detailed descriptions of related known technologies that may unnecessarily obscure the subject matter of the present invention will be omitted.

1 is a block diagram schematically showing a control flow of an emergency control system capable of monitoring and controlling abnormalities in a power conversion system and a battery management system according to the present invention, and FIG. 2 is A block diagram showing the control flow of the fault monitoring interface constituting the emergency control system according to the present invention, and FIG. 3 is a control flow chart of the emergency control system capable of intensive monitoring and control of abnormalities in the power conversion system and the battery management system according to the present invention. to be.

The emergency control system capable of monitoring and controlling abnormalities in the power conversion system and the battery management system according to the present invention, as shown in Figs. 1 and 2, stores the power of the grid power grid in the battery or supplies the power of the battery to the grid power grid. The power management system 20 that controls to be controlled, the battery management system 30 that manages the battery that stores power supplied from the grid power grid and performs data communication with the power management system 20, and the power stored in the battery. A power conversion system 40 that performs data communication with the power management system 20 and power management system 20 by converting AC/DC to charge or converting the power stored in the battery to DC/AC and supplying it to the grid or load, and performing data communication with the power management system 20 An energy management system 50 that manages energy by controlling each system through data communication with and a power meter 60 that displays the amount of power input and output from the grid power grid, and AC/DC conversion or DC/AC conversion of power. It is provided in the energy storage device including the converter (80, DC) and other equipment (70).

The emergency control system capable of monitoring and controlling abnormalities in the power conversion system and battery management system described above uses other ports in addition to the communication ports of the existing power management system 20, battery management system 30, and power conversion system 40. Therefore, it receives only abnormal data from the battery management system 30 and the power conversion system 40, determines whether or not there is a failure of each facility, and controls each facility to prevent a fire, and the battery management system 30 and the power conversion system It consists of a failure monitoring and control interface 10 that performs independent monitoring and control through the data communication of (30).

In this way, the fault monitoring and control interface 10 is directly connected to the battery management system 30 and the power conversion system 40 to transmit and receive data, thereby significantly shortening the communication cycle, thereby enabling a quick response when an abnormality occurs. And, it is possible to prevent accidents such as fire of the energy storage device through quick response in case of an abnormality.

It is preferable that the failure monitoring and control interface 10 does not receive all data from the battery management system 30 and the power conversion system 40, but only receives critical failure data. In addition, data communication between the fault monitoring and control interface 10 and the battery management system 30 or the power conversion system 40 is performed through a port different from the power management system 20, so that the response control is quickly performed. More preferable.

Here, the failure monitoring and control interface 10, as shown in Figure 2, the data receiving unit 11 for receiving the failure data of the battery management system 30 and the power conversion system 40, the received failure data Based on the recorded data recording unit 12 and the received failure data, the equipment control unit 14 that controls the battery management system 30 or the power conversion system 40, and the equipment by determining whether there is an abnormality according to the received failure data. It includes a data determination unit 13 for transmitting a control signal to the control unit 14.

The fault monitoring and control interface 10 does not record fault data received from the battery management system 30 and the power conversion system 40 in the database of the power management system 20, but only inputs a log through the data recording unit 12. It is desirable to do it. This is to ensure that data communication between the fault monitoring and control interface 10 and the battery management system 30 or the power conversion system 40 is performed in a fast cycle of less than 1 second.

In addition, the data determination unit 13 determines whether there is an abnormality according to the failure data transmitted from the battery management system 30 and the power conversion system 40, and then together with the failure data, the power management system 20 or the energy management system ( It is preferable to transmit the control information to 50) so that the power management system 20 or the energy management system 50 can also perform secondary supplementation. Accordingly, secondary supplementation by the power management system 20 or the energy management system 50 is possible for devices that have not been normally stopped even through the equipment control unit 14 of the failure monitoring and control interface 10. Safety is enhanced.

On the other hand, the battery management system 30 collects current read data, fault data, protection data, and alarm data, records fault data among these data, and transmits fault data through a data transmission unit, a fault monitoring and control interface 10. It is configured to transmit to the data receiving unit 11 of. In this case, it is preferable that the data transmission unit of the battery management system 30 transmits only the log without transmitting the entire fault data.

In addition, the power conversion system 40 collects the current read data, fault data, and warning data, records fault data among these data, and transmits fault data to the data receiving unit of the fault monitoring and control interface 10 through the data transmission unit. It is configured to transmit to (11). In this case, it is preferable that the data transmission unit of the power conversion system 40 also transmits only the log without transmitting the entire fault data.

On the other hand, it is preferable that the communication period between the fault monitoring interface 10 and the battery management system 30 or the power conversion system 40 is 0.5 to 1.0 seconds.

The emergency control using the emergency control system capable of centrally monitoring and controlling abnormalities in the power conversion system and battery management system of the present invention configured as described above will be described with reference to FIG. 3 as follows.

When the energy storage device is operated, the fault monitoring and control interface 10 of the emergency control system is operated to perform data communication with the battery management system 30 or the power conversion system 40. At this time, the communication period is preferably 0.5 to 1.0 seconds. When a failure occurs in the battery management system 30 or the power conversion system 40 and failure data is received by the data receiving unit 11, the location of the failure is identified.

When the fault location is the battery management system 30, the equipment control unit 14 sends a control signal to the battery management system 30 to first turn off the control switch of the battery management system 30, and then the power conversion system 40. Stop the operation of the power conversion system 40, the equipment control unit 14 sends a control signal to the power conversion system 40 to stop the operation of the power conversion system 40 first and manage the battery. Emergency control is performed by sending a control signal to the system 30 to turn off the control switch of the battery management system 30.

Then, the control result is transmitted to the power management system 20 together with the failure data stored in the data recording unit 12. Of course, the control result may be transmitted to the energy management system 50 on behalf of the power management system 20.

On the other hand, when a failure does not occur as a result of data communication between the failure monitoring and control interface 10 and the battery management system 30 or the power conversion system 40, or the control result is transmitted to the power management system 20, the power management system When a control signal is input to the failure monitoring and control interface 10 from (20), it is reconfirmed whether the operation state of the failure monitoring and control interface 10 is normal. When it is confirmed that the failure monitoring interface 10 operates normally, data communication with the failure monitoring interface 10 and the battery management system 30 or the power conversion system 40 is performed again, and the above process is repeated. And, if it is determined that the failure monitoring interface 10 does not operate normally, emergency control by the failure monitoring interface 10 is terminated.

Although described and illustrated in connection with some embodiments for exemplifying the technical idea of the present invention, the present invention is not limited to the configuration and operation as described above, and the scope of the technical idea described in the description of the invention It will be well understood by those skilled in the art that a number of changes and modifications can be made to the present invention without departing from it. Accordingly, all such appropriate changes and modifications and equivalents should be considered to be within the scope of the present invention.

10...Fault monitoring interface (I/F; Interface)
11...Data receiver
12...data log
13...data judgment unit
14...equipment control
20...Power Management System (PMS)
30...Battery Management System (BMS)
40...Power Conditioning System (PCS)
50...Energy Management System (EMS)
60...watt hour meter
70...Other equipment
80...Converter (DC; A/D Converter, D/C Converter)

Claims (5)

A power management system 20 for storing power of the grid power grid in a battery or controlling the power of the battery to be supplied to the grid power grid;
A battery management system 30 that manages a battery for storing power supplied from the grid power grid and performs data communication with the power management system 20;
A power conversion system 40 that converts and charges the power stored in the battery to AC/DC or converts the power stored in the battery to DC/AC and supplies it to the grid or load, and performs data communication with the power management system 20;
An energy management system 50 for managing energy by controlling each system through data communication with the power management system 20; And
As an emergency control system provided in an energy storage device including a power meter 60 and other equipment 70,
Abnormalities of the battery management system 30 and the power conversion system 40 by using a port separate from the communication port connecting the existing power management system 20 and the battery management system 30 and the power conversion system 40 It receives only data and controls each facility to determine the failure of each facility and prevents fire, and performs independent monitoring and control through data communication between the battery management system 30 and the power conversion system 30. Including a fault monitoring and control interface 10,
The battery management system 30 collects current read data, fault data, protection data, and alarm data, records fault data among these data, and transmits fault data to the fault monitoring and control interface 10 through a data transmission unit. and,
The power conversion system 40 collects current read data, fault data, and warning data, records fault data among these data, and transmits fault data to the fault monitoring and control interface 10 through a data transmission unit. Emergency control system capable of intensive monitoring and control of abnormal power conversion system and battery management system. The method of claim 1,
The failure monitoring and control interface 10 includes a data receiving unit 11 for receiving failure data of the battery management system 30 and the power conversion system 40, a data recording unit 12 for recording received failure data, and receiving The equipment control unit 14 that controls the battery management system 30 or the power conversion system 40 based on the fault data and transmits a control signal to the equipment control unit 14 by determining whether there is an abnormality according to the received fault data. Emergency control system capable of intensive monitoring and control of abnormalities in the power conversion system and the battery management system, characterized in that it comprises a data determination unit (13). The method of claim 2,
The data determination unit 13 determines whether there is an abnormality according to the fault data transmitted from the battery management system 30 and the power conversion system 40, and the control information is also used by the power management system 20 or the energy management system 50. Emergency control system capable of intensive monitoring and control of abnormalities in the power conversion system and the battery management system, characterized in that secondary supplementation is also possible in the power management system 20 or the energy management system 50 by transmitting. delete The method according to any one of claims 1 to 3,
A communication period between the fault monitoring and control interface 10 and the battery management system 30 or the power conversion system 40 is 0.5 to 1.0 seconds, and abnormal intensive monitoring and control of the power conversion system and the battery management system are possible. Emergency control system.

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